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A skin model using hair and skin cells can mimic human skin for research.

Tissue-engineered scaffolds help heal difficult wounds by supporting cell growth and repair.

Functionalized bacterial cellulose can improve medical tissue engineering.

Researchers created a model to understand heart aging, highlighting key genes and pathways, and suggesting miR-208a as a potential heart attack biomarker.

Scientists made a mouse that shows how a specific protein in the skin changes and affects hair growth and shape.

Different species and human skin models vary in their skin enzyme activities, with pig skin and some models closely matching human skin, useful for safety assessments and understanding the skin's protective roles.

Using CRISPR for gene editing in the body is promising but needs better delivery methods to be more efficient and specific.

Sebaceous gland organoids could improve skin regeneration and treatment.

The study concluded that the developed models are effective for studying hair growth mechanisms and testing new treatments.

The material combining eggshell protein and scaffold helps wounds heal faster and regenerates tissue effectively.

Cell-based models help test if cosmetic ingredients really work for hair growth and skin health.

Human skin models are essential for studying skin's sensory, immune, and nervous system interactions.

PBM helps improve cell survival in 3D tissue engineering.

Researchers developed a scaffold that releases a healing drug over time, improving wound healing and skin regeneration.

3D cell cultures produce extracellular vesicles similar to those in the body.

A systems biology approach helps improve mesenchymal stromal cell therapies by mapping interactions and identifying treatment targets.

Scientists developed a system to study human hair growth using skin cells, which could help understand hair development and improve skin substitutes for medical use.

Engineered skin substitutes can grow hair but have limitations like missing sebaceous glands and hair not breaking through the skin naturally.

Different levels of shear stress affect where cells move and gather in a 3D-printed model, helping to better understand cell behavior in blood vessels.

Scientists improved how to make skin-like structures from stem cells using special gels and a device that controls growth signals, leading to better hair and skin features.

The study created a new model to better understand human hair growth and health.

Better hair loss models needed for research.

The mouse model showed defects in adult stem cell maintenance related to Hutchinson-Gilford progeria syndrome.

Hair follicle culture helps study cell interactions and effects of substances on tissue growth.

The CAM is a useful model for studying burn wounds and testing treatments.

The document emphasizes the importance of ongoing research and ethical considerations in genome editing and cellular reprogramming.

Probiotic nanoscaffolds significantly improved burn healing and infection control in mice.

Injectable biomimetic gels can help heal tissues and deliver drugs but need improvements in strength and delivery.

Scientists created a new 3D skin model from cells of plucked hairs that works like real skin and is easier to get.

Rational design strategies are crucial for developing effective nanozymes for anti-inflammatory uses.